Influence of N-terminal acetylation and C-terminal proteolysis on the analgesic activity of beta-endorphin.

Removal of one, two and four amino-acid residues from the C-terminus of beta-endorphin ('lipotropin C-Fragment', lipotropin residues 61--91) led to the formation of peptides with progressively decreased analgesic potency; there was no change in the persistence of the analgesic effects. The four C-terminal residues are thus important for the activity of beta-endorphin, but not for the duration of action. Removal of eight amino-acid residues from the N-terminus provided a peptide that had no specific affinity for brain opiate receptors in vitro and was devoid of analgesic properties. The N-terminal sequence of beta-endorphin is therefore necessary for the production of analgesia, whereas the C-terminal residues confer potency. The N alpha-acetyl form of beta-endorphin had no specific affinity for brain opiate receptors in vitro and possessed no significant analgesic properties. Since lipotropin C'-Fragment (lipotropin residues 61--87) and the N alpha-acetyl derivative of beta-endorphin occur naturally in brain and pituitary and are only weakly active or inactive as opiates, it is suggested that proteolysis at the C-terminus and acetylation of the N-terminus of beta-endorphin may constitute physiological mechanisms for inactivation of this potent analgesic peptide.     

Biological and physical properties of a beta-endorphin analog containing only D-amino acids in the amphiphilic helical segment 13-31

Our approach to the modeling of beta-endorphin has been based on the proposal that three basic structural units can be distinguished in the natural peptide hormone: a highly specific opiate recognition sequence at the N terminus (residues 1-5) connected via a hydrophilic link (residues 6-12) to a potential amphiphilic helix in the C-terminal residues 13-31. Our previous studies showed the validity of this approach and have demonstrated the importance of the amphiphilic helical structure in the C terminus of beta-endorphin. The present model, peptide 5, has been designed in order to evaluate further the requirements of the amphiphilic secondary structure as well as to determine the importance of this basic structural element as compared to more specific structural features which might occur in the C-terminal segment. For these reasons, peptide 5 retains the three structural units previously postulated for beta-endorphin; the major difference with regard to previous models is that the whole C-terminal segment, residues 13-31, has been built using only D-amino acids. In aqueous buffered solutions as well as in 2,2,2-trifluoroethanol-containing solutions, the CD spectra of peptide 5 show the presence of a considerable amount of left-handed helical structure. Enzymatic degradation studies employing rat brain homogenate indicate that peptide 5 is stable in this milieu. In delta- and mu-opiate receptor-binding assays, peptide 5 shows a slightly higher affinity than beta-endorphin for both receptors while retaining the same delta/mu selectivity. In opiate assays on the guinea pig ileum, the potency of peptide 5 is twice that of beta-endorphin. In the rat vas deferens assay, which is very specific for beta-endorphin, peptide 5 displays mixed agonist-antagonist activity. Most remarkably, peptide 5 displays a potent opiate analgesic effect when injected intracerebroventricularly into mice. At equal doses, the analgesic effect of peptide 5 is less than that of beta-endorphin (10-15%) but longer lasting. In conjunction with our previous model studies, these results clearly demonstrate that the amphiphilic helical structure in the C terminus of beta-endorphin is of predominant importance with regard to activity in rat vas deferens and analgesic assays. The similarity between the in vitro and in vivo opiate activities of beta-endorphin and peptide 5, when compared to the drastic change in chirality in the latter model, demonstrates that even a left-handed amphiphilic helix formed by D-amino acids can function satisfactorily as a structural unit in a beta-endorphin-like peptide.     

Beta-endorphin. Biological activity of synthetic analogs with analgesia inhibiting property in rat vas deferens and guinea pig ileum assays

Three synthetic analogs of human beta-endorphin (beta h-EP) (I, [Gln8, Gly31]-beta h-EP-Gly-Gly-NH2; II, [Arg9,12,24,28,29]-beta h-EP and III, [Cys11,26, Phe27, Gly31]-beta h-EP), which have been shown to possess potent inhibiting activity to beta h-EP-induced analgesia, were assayed in rat vas deferens and guinea pig ileum bioassay systems. In the rat vas deferens assay, relative potencies of these analogs were beta h-EP, 100; I, 30; II, 40; III, 1, whereas in the guinea pig ileum assay: beta h-EP, 100; I, 184; II, 81; III, 163. From previous studies on their analgesia potency in mice and opiate receptor-binding activity in rat brain membranes, their activity in rat vas deferens correlates well with the analgesic potency and the activity from guinea pig ileum assay shows good correlations with that from the opiate receptor-binding assay.     

Synthesis and receptor binding activity of elephant beta-endorphin, a beta-endorphin homolog with highly potent analgesic activity.

Elephant beta-endorphin and its analog, elephant beta-endorphin(6-31) were synthesized by standard solid phase method. Receptor binding activity showed that elephant beta-endorphin was five to six times more potent than human beta-endorphin in its ability to bind to opiate receptors on rat brain membrane. In a previous study (Wong, C.-L., Wai, M.-K., Cheng, H.-C., Chung, D. & Yamashiro, D (1990) Clinical and Experimental Pharmacology and Physiology 16, 33-37), tail flick test for intracerebroventricularly administered beta-endorphin showed that the antinociceptive potency of elephant beta-endorphin was seven to eight times higher than that of human beta-endorphin in mice. Results from both studies suggest that elephant beta-endorphin was a much more potent antinociceptive agent than human beta-endorphin in tail flick test and its higher analgesic activity might be due to its higher affinity for opiate receptors in the brain.     

Analgesic activity of double endorphins in vivo

The effects of double endorphins DALA2, DYNO2, CASO2 on pain threshold in the rats were compared with those of DALA (D-Ala2-Met5-enkephalinamide). Marked differences in the analgesic potency of the investigated peptides were noted. The most potent analgesic effect was exerted by DALA2. DYNO2 was weaker than DALA and DALA2 due to lack of glycine residue in position 3, probably responsible for the receptor affinity and analgesic activity in vivo. The weak analgesic activity of CASO2 in vivo corresponds with the weak opiate agonistic action of this peptide in vitro [see 7]. All investigated peptides induced changes in animal behaviour when injected i.c.v. The results indicated that among peptides in the novel group of double endorphins, DALA2 is of special interest because of a potent and long lasting analgesic action.     

Opiate binding properties of naturally occurring N- and C-terminus modified beta-endorphins

Beta-endorphin is further processed within the pituitary and brain by either N-terminal acetylation, carboxy-terminal proteolysis, or both. These naturally occurring analogues are stored intracellularly and, in some tissues, represent the majority of beta-endorphin immunoreactivity detected by antisera. It is therefore critical to determine their relative potencies at the opiate receptor. This study demonstrates that cleavage of the C-terminus tetrapeptide brings about a 10-fold decrease in opiate binding potency of either camel or human beta-endorphin. N-Acetylation, on the other hand, causes over a thousand fold loss in opiate potency rendering the peptide effectively inactive. Since unmodified beta-endorphin is approximately equipotent at multiple opiate receptors, we tested for possible differential shifts towards mu or delta-type receptors which may result from the modification. Our results show no change in selectivity, but simply an overall loss of potency.     

Human beta-endorphin. Synthesis and biological activity of analogs with modification in residue positions 8, 27, and 9 or 11

Three analogs of human beta-endorphin (beta h-ER) were synthesized by the solid-phase method: [Gln8,Trp27]-beta h-EP (I), [Gln8,Arg9,Trp27]-beta h-EP (II), and [Gln9,Arg11,Trp27]-beta h-EP (III). Radioreceptor binding assay with use of tritiated beta h-EP as primary ligand gave relative potencies as follows: beta h-EP, 100;I, 778;II, 467;III, 449. Relative potencies in an analgesic assay were: beta h-EP, 100;I, 114;II, 165;III, 83. The 8-11 segment of beta h-EP can tolerate a net increase in charge of +2 without diminishing analgesic potency. The substitution of Glu8 may be one of the more dependable means of designing beta-endorphin antagonists.     

Examination of the requirement for an amphiphilic helical structure in beta-endorphin through the design, synthesis, and study of model peptides

In our approach to beta-endorphin modeling, we have proposed that the biological properties of the natural peptide are determined by the combination of three basic structural units: a highly specific opiate recognition sequence at the NH2 terminus (residues 1-5) connected via a hydrophilic peptide link (residues 6-12) to a potential amphiphilic helix in the COOH-terminal residues 13-31. In the alpha-helical conformation the hydrophobic domain twists around the length of the helix and covers almost one-half of its surface. The other distinctive features of the helix include its basicity and the two aromatic residues Phe18 and Tyr27. In contrast to previous models we have studied, peptide 4 is a "negative" model in the sense that it was designed and examined in order to determine how the lack of a well defined amphiphilic structure affects the biological properties of beta-endorphin. For this purpose, peptide 4 retains the three structural units previously postulated for beta-endorphin, but the amino acids of the 13-31 region are arranged in such a way that no definite continuous hydrophobic zone could be formed in an alpha- or pi-helical conformation of this region. In aqueous buffered solutions, peptide 4 showed almost the same amount of alpha-helical structure as beta-endorphin, with a slight tendency toward less helicity in 50% aqueous 2,2,2-trifluoroethanol. In rat brain homogenate, peptide 4 was degraded slightly slower than beta-endorphin, in contrast to the apparently much higher stability of previous models under the same conditions. With regard to opiate receptor binding, peptide 4 was twice as potent as beta-endorphin in mu-receptor assays but half as potent in delta-receptor assays. The opiate potency of peptide 4 on the guinea pig ileum was higher than that of beta-endorphin. In contrast, in the rat vas deferens assay, which is very specific for beta-endorphin, the potency of peptide 4 was very low and could be shown not to be mediated by the same opiate mechanism or by the same opiate receptor. A comparison of these results with those of previous model peptides provides further evidence for the importance of an amphiphilic helical structure in beta-endorphin residues 13-31, which determines the resistance to proteolysis of the natural molecule and contributes to the delta- and mu-opiate receptor interaction. The amphiphilicity of this helical structure must also be essential for high opiate activity on the rat vas deferens (epsilon-receptors), whereas no such structural requirement appears to be necessary for interaction with the opiate receptors on the guinea pig ileum.     

Inhibition of analgesia by C-terminal deletion analogs of human beta-endorphin

Human beta-endorphin (beta h-EP) analogs of variable chain lengths have been investigated for their potency in inhibiting analgesia induced by beta h-EP or by the potent opiate etorphine. It was found that beta h-EP-(1-28) inhibits the analgesic effect of beta h-EP and etorphine when co-injected intracerebroventricularly into mice. Antagonism by competition at same opioid receptor subtypes is suggested from parallel shifts of the dose-response curve of etorphine or beta h-EP in the presence of increasing doses of beta h-EP-(1-28). On a molar basis, beta h-EP-(1-28) is nearly 10 times more potent than naloxone. The reduction of the chain length from residues 1-28 to 1-27 lowered the antagonist potency while further reduction of the peptide chain led to a complete loss of inhibitory activity. From comparison of the opioid-receptor binding affinity, analgesic activity and antagonist potency, it is concluded that the C-terminus of beta-EP is critical to the biological efficacy of the molecule and that the antagonist activity of C-terminal deletion analogs is probably mediated through residues 27 and 28.     

Potencies of naturally-occurring AKH/RPCH peptides in Locusta migratoria in the acetate uptake assay in vitro and comparison with their potencies in the lipid mobilisation assay in vivo

The biological potencies of a number of naturally-occurring octa- and decapeptides of the large AKH/RPCH family of peptides were determined in Locusta migratoria using the lipid-mobilising assay in vivo and the acetate uptake assay in vitro. The most potent of the newly-tested peptides in the in vitro assay, Phl-CC, differs from the endogenous major locust peptide, Lom-AKH-I, only by an exchange of serine versus threonine at position 10. However, the most active peptide in the in vitro assay remains Lom-AKH-III. At the other extreme is the peptide Mem-CC which contains a tyrosine residue at position 4 rather than the more typical phenylalanine. This peptide is over 20,000 times less potent than Lom-AKH-III in the in vitro assay, and also results in an unusual dose-response curve in the in vivo assay. Only a few peptides are approximately equipotent in both assays, but mostly the bioanalogues have a higher potency in vitro. The majority of them are 2- to 10-fold more potent in vitro, but Ani-AKH and Lom-AKH-III are 19- and 48-fold more potent. The results are discussed in relation to either the actions of proteases or of possible preferential binding of different receptors involved in the different assays.     

Mu and delta receptors: their role in analgesia in the differential effects of opioid peptides on analgesia

Utilizing the mouse tail-flick assay, the rank order of analgesic potency for various opioids (i.c.v.) is beta h-endorphin greater than D-Ala2-D-Leu5-enkephalin greater than morphine greater than D-Ala2-met-enkephalinamide much greater than met-enkephalin much greater than leu-enkephalin. Assuming mu receptor mediation of analgesia, there is an affinity and analgesic potency (ie: D-Ala2-Leu5-enkephalin has 1/7 the affinity of morphine for the mu receptor but is 18X more potent as an analgesic). Additionally, sub-analgesic doses of various opioid peptides have opposite effects on analgesic responses. Leu-enkephalin, D-Ala2-D-Leu5-enkephalin or beta h-endorphin potentiate morphine or D-Ala2-met-enkephalinamide analgesia whereas met-enkephalin or D-Ala2-met-enkephalinamide antagonize opioid-induced analgesia. Using the enkephalins as the prototypic delta ligands (100 fold selective) and based on their effects on analgesia, we suggest that Leu-enkephalin-like peptides interact with the delta receptor as an "agonist" to facilitate and met-enkephalin-like peptides as an "antagonist" to attenuate analgesia. Given the biochemical evidence of a coupling between mu and delta receptors, we suggest that the mechanism of facilitation or attenuation of analgesia by the enkephalins is a direct in vivo consequence of this coupling. Further, the analgesic potencies of various opioid ligands can be better correlated to the combination of their simultaneous occupancy of mu and delta receptors.     

Beta-endorphin: peripheral opioid activity of homologues from six species

The peripheral opioid activity of six homologous beta-endorphins (beta-EPs) were assayed on the guinea pig ileum and the vas deferens of the mouse, the rat and the rabbit. In the guinea pig ileum assay, human beta-EP (beta h-EP) was less potent than camel, turkey, and ostrich beta-EPs, of the same potency as equine beta-EP and more active than des-acetyl salmon beta-EP. In the rat vas deferens, mammalian beta-EPs showed higher activity than those from the bird and the fish, whereas in the mouse vas deferens assay, beta h-EP is more active than those from other species. In the rabbit vas deferens, however, all homologous beta-EPs show very weak activity. The relative potency of beta-EP homologues obtained from rat vas deferens assay is in good correlation with the analgesic potency, while the receptor binding activity does not correlate with any of the four bioassays, but appears to be related to the charge properties of the peptides.     

Synthesis and analgesic activity of human beta-endorphin analogs substituted at positions 17, 18, or 19

Three peptide analogs of beta-endorphin which are substituted in positions 17, 18 or 19 have been synthesized and their analgesic potencies have been measured by the tail-flick method in mice. The results showed that the replacement of Phe-18 or Lys-19 by alanine reduced the potency to 15% whereas the replacement of Leu-17 by alanine reduced the analgesic potency to 68%.     

beta-endorphin: synthesis and biological activity of shortened peptide chains

Three analogs of beta-endorphin have been synthesized by the solid-phase method: betac-endorphin-(1--5)-(28--31), betac-endorphin-(6--31) and betah-endorphin-(1--5)-(16--31). The analgesic activities of these synthetic peptides relative to that of the parent molecule are reported. All three peptides at high doses exhibit either no or much weaker analgesic activity than beta-endorphin. These data suggest that the entire beta-endorphin molecule is necessary for full in vivo analgesic activity.     

Structure-activity studies of vasoactive intestinal polypeptide.

This report explores the potential side-chain functional groups required for interaction of the bronchodilator neuropeptide, vasoactive intestinal peptide (VIP), with its receptor. The binding affinity and biological activity of native VIP have been found to be sensitive to the removal of amino- and carboxyl-terminal residues. This data suggests that elements within the entire primary sequence of the VIP molecule appear to be necessary for recognition by VIP receptors. The introduction of alanine residues substituted into the VIP molecule is utilized to probe for side-chain functional groups that are crucial for eliciting high receptor binding affinity in vitro and high biological potency in vivo. The VIP pharmacophore appears to be identical in guinea pig lung and human lung and consists of multiple binding sites most likely involving positions Asp3, Phe6, Thr7, Tyr10, Tyr22, and Leu23. These findings could be exploited to enhance the biological potency of VIP by increasing the binding energy at these positions.     

Calcitonin induced increase in ACTH, beta-endorphin and cortisol secretion

The response of ACTH, beta-endorphin and cortisol to calcitonin administration was investigated in 8 subjects with recent fractures of the vertebrae due to postmenopausal or senile osteoporosis (Ost) and in seven normal healthy controls (NC). A significant increase of the three hormones was observed in 13 subjects. The maximum increase was observed between 15 and 60 min.: the cortisol level (microgram/100 ml) rose from 14.3 +/- 1.9 to 24.8 +/- 3.2 (P less than 0.05) in Ost and from 7.7 +/- 0.6 to 21.7 +/- 1.7 (P less than 0.001) in NC, the beta-endorphin (pmol/l) from 5.8 +/- 0.6 and to 21.2 +/- 1.3 in OST (P less than 0.001) and from 5.9 +/- 0.4 to 21.9 +/- 4.5 (P less than 0.01) in NC and the ACTH levels (pg/ml) from 21.3 +/- 5.7 to 61.7 +/- 3.6 (P less than 0.001) in OST and from 30.0 +/- 6.2 to 58.8 +/- 7.5 (P less than 0.05) in NC. The results indicate a possible role of calcitonin in modulating the anterior pituitary function. It also suggests that the analgesic effect of calcitonin might be mediated by the increase of beta-endorphin. The possibility that this analgesic effect of calcitonin is due to its direct binding to the opiate receptors was excluded in the present study by in vitro binding assay.     

Possible involvement of cerebroside sulfate in opiate receptor binding.

Cerebroside sulfate (CS) appears to fulfill most of the structural requirements of a hypothetical opiate receptor. It possesses many of the properties that are thought to be necessary for the identification of an "opiate receptor," exhibiting high affinity and stereoselective binding to a number of narcotic drugs. Although these properties are insufficient to establish identity of the receptor, it is highly significant that the affinity of this binding can be correlated with the analgetic potency of these drugs in both man and rodents. CS is an endogenous component of brain tissue, and a partially purified opiate receptor from mouse brain has been found to be CS. Other experiments indicate that reduced availability of brain CS decreases the analgetic effects of morphine and this is accompanied by a reduction in number of binding sites, suggesting that the interaction of opiates with CS observed in vitro may also have importance in vivo. CS was also found to be a component of the opiate receptor after marking with 125I-labeled diazosulfanilic acid. The possibility that CS or the SO4-2 group of this lipid may be the "anionic site" of the opiate receptor should be considered.     

Unexpected opioid activity in a known class of drug

Tifluadom, although structurally a 1,4 benzodiazepine, has no affinity for the 3H-flunitrazepam binding site, but is a potent displacer of 3H-bremazocine from its opioid binding site. Tifluadom is characterised as an opiate kappa-receptor agonist in vitro and in vivo with potent analgesic activity in animals and no dependence potential.     

Pharmacology and neurochemistry of bombesin-like peptides

The pharmacology and neurochemistry of bombesin-like peptides was investigated. Synthetic analogues which had modifications near the N-terminal inhibited specific binding of (125I-Tyr4)BN with high affinity in rat brain and these peptides were potent hypothermic agents after central injection. In comparison, BN-like peptides with modifications near the C-terminal bound with low affinity and were not potent hypothermic agents. These data indicate that the C-terminal of BN is required for central high affinity binding and biological potency. Because substitution of D for L-amino acids at the 8, 10, 13 or 14 positions greatly reduced receptor binding affinity and ability to induce hypothermia, central receptors for BN show marked stereospecificity. Also, the pharmacology of BN in the periphery was investigated using dispersed guinea pig pancreatic acini and found to be similar to that of the brain. Because endogenous BN-like peptides extracted from brain tissue possess appreciable biological activity, these receptors are likely activated by endogenous BN-like peptides in vivo.     

Hemorphins, cytochrophins, and human beta-casomorphins bind to antiopiate (TYR-MIE-1) as well as opiate binding sites in rat brain

Novel peptides with opiate activity, derived from endogenous sources (human and bovine casomorphins from milk, hemorphins from hemoglobin, and cytochrophins from mitochondrial cytochrome b), were tested for their ability to inhibit binding of the brain peptide Tyr-MIF-1 (Tyr-Pro-Leu-Gly-NH2) to its high affinity sites in rat brain. The order of potency in inhibiting binding of 125I-Tyr-MIF-1 was: hemorphin and bovine casomorphins greater than Tyr-MIF-1 greater than cytochrophins greater than human casomorphins. Naloxone and DAMGO were ineffective at inhibiting Tyr-MIF-1 binding. The results provide evidence that, in addition to their ability to bind to mu opiate receptors, these novel endogenous peptides with opiate activity and a peptide (Tyr-MIF-1) with antiopiate properties also bind to a non-opiate site labeled by Tyr-MIF-1. These sites could be involved in a balance between opiate and antiopiate peptides.